RADIATION THERAPY ONCOLOGY GROUP



RADIATION THERAPY ONCOLOGY GROUP

RTOG 0631

PHASE II/III STUDY OF IMAGE-GUIDED RADIOSURGERY/SBRT

FOR LOCALIZED SPINE METASTASIS

Study Chairs (3/18/11)

|Principal Investigator/Radiation Oncology |Translational Research Co-Chair |

|Samuel Ryu, MD |Adam Dicker, MD, PhD |

|Henry Ford Hospital |Thomas Jefferson University |

|2799 W. Grand Blvd. |111 S. 11th Street |

|Detroit, MI 48202 |Philadelphia, PA 19107 |

|313-916-1027/FAX 313-916-3235 |215-955-627/FAX 215-955-0412 |

|sryu1@ |mailto:adamdicker18@ |

| | |

|Neurosurgery Co-Chair |Quality of Life Co-Chair |

|Peter Gerszten, MD, MPH |Benjamin Movsas, MD |

|University of Pittsburgh Medical Center |Henry Ford Health System |

|200 Lothrop Street, Suite A-402 |2799 W. Grand Blvd. |

|Pittsburgh, PA 15213 |Detroit, MI 48202 |

|412-647-5644/FAX |313-916-5188/FAX 313-916-3235 |

|gersztenpc@upmc.edu |bmovsas1@ |

| | |

|Medical Physics Co-Chair |Senior Statistician |

|Fang-Fang Yin, PhD |Stephanie Shook, PhD |

|Duke University Medical Center |Radiation Therapy Oncology Group/ACR |

|Box 3295 |1818 Market Street, Suite 1600 |

|Durham, NC 27710 |Philadelphia, PA 19013 |

|919-660-2185/FAX |215-574-0850/FAX 215-928-0153 |

|fangfang.yin@duke.edu |sshook@ |

| | |

|Radiation Oncology/IGRT Co-Chair | |

|Robert D. Timmerman, MD | |

|University of Texas Southwestern | |

|5801 Forest Park Road, NF3.302B | |

|Dallas, TX 75390-9183 | |

|214-645-7651/ FAX 214-645-7622 | |

|Robert.Timmerman@UTSouthwestern.edu | |

Document History

| |Version/Update Date |Broadcast Date |

|Amendment 4 |August 30, 2011 |September 22, 2011 |

|Amendment 3 |March 18, 2011 |May 19, 2011 |

|Amendment 2 |March 11, 2010 |March 23, 2010 |

|Update |December 1, 2009 |December 1, 2009 |

|Amendment 1 |November 6, 2009 |November 19, 2009 |

|Update |August 11, 2009 |August 11, 2009 |

|Update |August 7, 2009 |August 7, 2009 |

|Activation |July 20, 2009 |August 7, 2009 |

RTOG Headquarters

1-800-227-5463, ext. 4189

INDEX

Schema

Eligibility Checklist

1.0 Introduction

2.0 Objectives

3.0 Patient Selection

4.0 Pretreatment Evaluations/Management

5.0 Registration Procedures

6.0 Radiation Therapy

7.0 Drug Therapy

8.0 Surgery

9.0 Other Therapy

10.0 Tissue/Specimen Submission

11.0 Patient Assessments

12.0 Data Collection

13.0 Statistical Considerations

References

Appendix I - Sample Consent Form

Appendix II - Study Parameters

Appendix III - Performance Status Scoring

Appendix IV - Neurological Examination

Appendix V - Blood Collection

Appendix VI - Urine Collection

RADIATION THERAPY ONCOLOGY GROUP

RTOG 0631

Phase II/III Study of Image-Guided Radiosurgery/SBRT

for Localized Spine Metastasis

SCHEMA (8/30/11)

|PHASE II COMPONENT |

|R | |

|E | |

|G |Radiosurgery/SBRT: |

|I |Single fraction dose of 16 Gy |

|S | |

|T | |

|E | |

|R | |

|PHASE III COMPONENT |

|S | |R | |

|T |Number of Spine Metastases |A |Arm 1: Radiosurgery/SBRT: |

|R |1) 1 |N | Single fraction dose of 16 or 18 Gy** |

|A |2) 2-3 |D | |

|T | |O |Arm 2: External Beam Radiation Therapy: |

|I |Type of Tumor |M | Single fraction dose of 8 Gy |

|F |1) Radioresistant tumor* |I | |

|Y |2) Other |Z |Randomization ratio (Arm 1: Arm 2) = 2:1 |

| | |E | |

| |Intended Radiosurgery/SBRT Single Fraction | | |

| |Dose** | | |

| |1) 16 Gy | | |

| |2) 18 Gy | | |

*Radioresistant tumors include soft tissue sarcomas, melanomas, and renal cell carcinomas.

**Patients randomized to Arm 1 (experimental arm) will be stratified according to the single fraction dose for image-guided radiosurgery/SBRT, using either 16 or 18 Gy as preferred by the treating physician.

See Section 5.0 for pre-registration requirements; see Section 6.0 for details of radiosurgery; see Section 11.2 and Appendix II for follow-up requirements.

Patient Population: (See Section 3.0 for Eligibility)

Patients with localized spine metastasis from the C1 to L5 levels (a solitary spine metastasis; 2 separate spine levels; or up to 3 separate sites); each of the separate sites must have a maximal involvement of 2 contiguous vertebral bodies.

Required Sample Size: Phase II component: 43 patients; 8/30/11: Completed

Phase III component: 240 patients

RTOG Institution #

RTOG 0631 ELIGIBILITY CHECKLIST (8/30/11)

Case # (page 1 of 3)

_____ (Y) 1. According to a screening imaging study, is there localized spine metastasis from the C1 to L5 (a solitary spine metastasis); two separate spine levels; or up to 3 separate sites (e.g. C5, T5-6, and T12)?

_____ Specify screening imaging study (bone scan, PET, CT scan, or MRI)

_____ (Y) 2. Is the patient’s Zubrod Performance Status 0-2?

_____ (Y) 3. Is the patient > 18 years old?

_____ (Y) 4. Has a history and physical been performed within 2 weeks prior to registration?

____ (Y) 5. Has a MRI of the involved spine been performed within 4 weeks prior to registration?

_____ (Y) 6. Has the Numerical Rating Pain Scale been performed within 1 week prior to registration with a

score of > 5 for at least one of the planned sites for spine radiosurgery?

_____ (Y) 7. Has the patient had a neurological exam within 1 week prior to registration to rule out rapid neurologic decline?

_____ (Y) 8. If epidural compression is present, is there a > 3mm gap between spinal cord and the edge of the

epidural lesion?

_____(Y) 9. If the patient has a paraspinal mass (≤ 5 cm in greatest dimension), is it contiguous with the spine metastasis?

(Y/NA) 10. If a women of child bearing potential, has the patient had a negative serum pregnancy test within 2 weeks prior to registration?

(Y) 11. If a woman of child bearing potential or a sexually active male, is the patient willing to use effective

contraception while on treatment?

______(Y) 12. Has the patient signed the informed consent?

______(N) 13. Does the patient have myeloma or lymphoma? other visceral metastasis and radioresistant tumors (including soft tissue sarcomas, melanomas, and renal cell carcinomas) are eligible).

______(N) 14. Is the patient non-ambulatory?

______(Y) 15. Are all spinal metastases planned to be treated according to the protocol?

______(N) 16. Is there spinal instability due a compression fracture?

______(N) 17. > 50% loss of vertebral body height?

______(N) 18. Is frank spinal cord compression or displacement or epidural compression within 3 mm of the spinal cord?

______(N) 19. Is bony retropulsion causing neurologic abnormality?

______(N) 20. Has the patient received prior radiation to the index spine?

______(N) 21. Is an MRI of the spine medically contraindicated for the patient?

(Continued on next page)

RTOG Institution #

RTOG 0631 ELIGIBILITY CHECKLIST (8/7/09, 11/6/09)

Case # (page 2 of 3)

The following questions will be asked at Study Registration:

CREDENTIALING FOR IMRT and IMAGE-GUIDED SPINE RADIOSURGERY IS REQUIRED BEFORE REGISTRATION.

1. Name of institutional person registering this case?

(Y) 2. Has the Eligibility Checklist (above) been completed?

(Y) 3. Is the patient eligible for this study?

4. Date the patient provided study-specific consent prior to study entry

5. Patient’s Initials (First Middle Last) [May 2003; If no middle initial, use hyphen]

6. Verifying Physician

7. Patient’s ID Number

8. Date of Birth

9. Race

10. Ethnic Category (Hispanic or Latino; Not Hispanic or Latino; Unknown)

11. Gender

12. Patient’s Country of Residence

13. Zip Code (U.S. Residents)

14. Method of Payment

15. Will any component of the patient’s care be given at a military or VA facility?

16. Calendar Base Date

17. Registration/randomization date: This date will be populated automatically.

(Continued on next page)

RTOG Institution #

RTOG 0631 ELIGIBILITY CHECKLIST (8/30/11)

Case # (page 3 of 3)

(Y/N) 18. Blood kept for cancer research?

(Y/N) 19. Urine kept for cancer research?

(Y/N) 20. Blood kept for medical research?

(Y/N) 21. Urine kept for medical research?

(Y/N) 22. Allow contact for future research?

For Phase III Component Only:

(N/Y) 23. Did the patient agree to participate in the quality of life component?

If no, please specify the reason from the following:

1. Patient refused due to illness

2. Patient refused for other reason: specify _____________

3. Not approved by institutional IRB

4. Tool not available in patient’s language

5. Other reason: specify_________________

24. Specify number of spine metastases (1 vs. 2-3)

1. 1

2. 2-3

____________25. Specify type of tumor

1. Radioresistant tumors (include soft tissue sarcomas, melanomas and renal cell carcinomas)

2. Other

____________26 Specify RT dose

1. 16Gy

2. 18Gy

The Eligibility Checklist must be completed in its entirety prior to web registration. The completed, signed, and dated checklist used at study entry must be retained in the patient’s study file and will be evaluated during an institutional NCI/RTOG audit.

Completed by Date

1.0 INTRODUCTION

1.1 SPINE METASTASIS

Spine metastases are a common complication of cancer. While similar to other bone metastases in terms of vertebral bone involvement, spine metastases have unique clinical considerations. One is spinal bone pain, which is the most common initial presenting symptom. The other is that these metastases can present with a soft tissue mass at the paraspinal area or as an epidural compression. Therefore, patients with spinal metastases invariably have severe back pain, often with associated neurological problems, which can further compromise their performance status.

The main presenting symptom of spine metastases is back pain. Therefore, the primary goal of radiosurgery for spinal metastases is pain control (relief). The treatment of spine metastases has largely been with conventional fractionated radiotherapy. Although the most common regimen of radiotherapy has been 30 Gy in 10 fractions, the radiation dose-pain response has not been well settled. An early RTOG study for bone metastasis reported that low-dose short course radiotherapy was as effective as a high dose protracted regimen (Tong 1982). Recently, RTOG 97-14, which randomized the treatment of bone metastasis between a single dose of 8 Gy and 10 fractions of 3 Gy for a total dose of 30 Gy, also showed a similar result. However, the duration and rate of pain control of bone metastases was limited by the conventional method of radiotherapy in both arms (Hartsell 2005). In a subgroup of patients with spine metastases in this study, only 61% of patients experienced partial or complete pain relief at 1 month post-treatment. Recently, there has been an increasing trend of diagnosing more localized spine metastases (i.e., oligometastases), although the true incidence of solitary spine metastasis is not known. These patients may have a prolonged survival time. Therefore, there is pressing need to improve the pain control of patients with spine metastases, which may be connected to an improvement in quality of life.

Despite the common occurrence of spine metastases, there have been few prospective studies for this large group of patients (Greenberg 1980; Young 1980; Maranzano 1995; Helweg-Larsen 1996; Patchell 2005). It is evident, from these studies, that a single dose of 8-10 Gy is equivalent to a fractionated regimen of 30 Gy in 10 fractions. This suggests that a further increase in the single dose of radiation may improve the rate of pain control. The difficulty is that there is a dose-limiting organ, the spinal cord, within close proximity to the vertebral body, and spine metastases often are present with epidural tumor masses. Therefore, accurate targeting and radiation intensity-modulation will be required to minimize the spinal cord dose. In this effort, radiosurgery has emerged as an innovative treatment option for spinal metastases. While the spine region does have the benefit of minimal breathing-related organ movement and easy imaging, safely delivering a more intensive dose of radiation requires not only precise targeting due to the proximity of the spinal cord, but also accurate treatment planning and delivery.

1.2 Radiosurgery/SBRT of Localized Spine Metastasis

Preclinical physical and dosimetric studies have demonstrated the applicability of patient positioning, immobilization, and dosimetric characteristics of spinal radiosurgery for spine metastases (Yin 2002; Yin 2002b). The first approach to establish clinical feasibility was to determine the accuracy and precision of radiosurgery to treat the spine and epidural/paraspinal tumors that are adjacent to the spinal cord. This clinical study demonstrated targeting accuracy within 1.5 mm for actual patient treatment (Ryu 2003). The accuracy of radiosurgical targeting for spine has been reported with various technologies (Ho 2007; Yin 2008).

Subsequent clinical experience with single dose radiosurgery for spinal metastasis showed the efficacy of radiosurgery for pain control and improvement of neurological function in patients with epidural compression. In these studies, there was rapid pain relief reported with a median time to pain relief of only 2 weeks, with pain control seen in some patients as early as within 24 hours (Ryu 2003; Gertzen 2005; Degen 2005; Ryu 2004). Median duration of pain control in the treated spine region was 13.3 months (Ryu 2008). Other investigators also demonstrated similar results of pain control in patients with spine metastasis (Gertzen 2005; Degen 2005; Gertzen 2006; Gertzen 2005b). Quality of life also was improved secondary to pain control (Degen 2005). Local tumor control at the treated spine was achieved in 95% of the patients. Recurrence at the immediately adjacent vertebrae was less than 5% (Ryu 2004). Patients with oligometastasis had a longer survival with more effective local treatment of the spine metastasis (Ryu 2007). This suggests that a more intensive treatment may be appropriate for patients with localized spine metastases in order to improve their clinical outcome and quality of life. A single institution clinical trial of radiosurgery for epidural spinal cord compression showed that thecal sac patency was achieved in 82% of patients by radiographic reduction of epidural or paraspinal tumors (Ryu 2008c).

Spinal cord as the dose-limiting critical organ at risk is a key concern. Because of the nature of radiosurgery with rapid dose fall-off, there is a radiation dose gradient within the diameter of the spinal cord. The result of accumulated dose volume histogram (DVH) analyses of the spinal cord in 230 procedures at Henry Ford Hospital showed a partial volume tolerance of the spinal cord of 10 Gy to the 10% cross-sectional area of the cord, provided that the spinal cord is defined as 6 mm above and below the radiosurgery target volume (Ryu 2007). Other investigators used slightly different criteria of defining the spinal cord dose: these were a maximum dose of 12-14 Gy at the surface of an MRI-defined or myelogram-defined spinal cord (Chang 2007) or a maximum dose of 10 Gy in a myelogram-defined spinal cord (Yamada 2008). Taken together, these dose criteria were in a similar range. Therefore, we chose to use the spinal dose constraint as 10 Gy to 10 % of the spinal cord defined as a maximum of 6 mm above and below the radiosurgery target.

1.3 Selection of Radiosurgery Dose (8/30/11)

A radiation dose-response relationship for pain control has not been established. However, there is a trend for a radiation dose-pain control relationship when all the studies are compiled. A recent meta-analysis of ten randomized trials containing single fraction radiotherapy for painful bone metastasis showed single-fraction radiation (median 8 Gy, range 8-10 Gy) achieved a complete pain response of 33.4%, and an overall response rate of 62.1% (Wu 2003). Large scale clinical trials using single fraction radiation doses of 8 Gy resulted in similar pain control of bone metastasis (Hartsell 2005; Bone Pain Trial Working Party 1999; Steenland 1999). Therefore, the phase III portion of this trial will use either 8 Gy as the prescribing radiation dose; 3-dimensional conformal beam arrangement is also allowed per the treating physician’s discretion.

Radiosurgery experiences recently have been reported with a single fraction of higher radiation doses for spinal metastasis. The majority of the spine metastases consistently responded to the higher doses of radiosurgery. Although the results cannot be directly compared to each other, these results suggest a trend towards a higher overall pain control with higher radiation doses (Ryu 2003; Ryu 2004; Gertzen 2006; Gertzen 2005b). There is no threshold dose that can be firmly stated. Based on the Henry Ford Hospital experience of radiosurgery dose escalation from 10 Gy to 20 Gy in 2 Gy increments, there was a strong trend for increasing pain relief with higher radiation doses, particularly when a dose ≥ 16 Gy was employed (Ryu 2008; Ryu 2007).While there was no statistically significant difference, the sample size may have been the main limiting issue to detect a statistical difference in the dose-response analysis. When the radiosurgery dose was ≥ 16 Gy, the probability of pain relief was reached in over 80% of the patients. The experience of the University of Pittsburgh also showed consistent results of pain relief with a median dose ≥ 16 Gy (Gerzten 2005; Gertzen 2005b; Gertzen 2006). Therefore, the phase III component of this study will use 16 or 18 Gy in 1 fraction. The spinal cord constraint is 10 Gy to the 10% partial spinal cord volume (spinal cord defined as a maximum of 6 mm above and below the target volume) [Ryu 2007].

Additional experience of radiosurgery with higher doses for spine metastasis suggest that a higher (than 16 Gy) radiosurgery dose was required to achieve similar pain relief, particularly in radioresistant tumors including soft tissue sarcoma, melanoma, and renal cell carcinoma as well as other tumors. (Gerszten 2005c; Nguyen 2010, Yamada 2008). Therefore, the phase III component of this study will use a radiosurgical dose of 16 Gy or 18 Gy per treating physician’s discretion and institutional experience. Maximum tolerated dose (MTD) has not been defined in spine radiosurgery, as the MTD of the spinal cord is not known. In this clinical trial, the proposed prescription doses are readily achievable with the defined spinal cord tolerance constraint described in Sections 1.2 and 6.3.1.2.

1.4 Advantages of Image-Guided Radiosurgery (8/30/11)

The potential advantages of using image-guided radiosurgery for spine metastasis are many. First, pain control is rapid and durable. Second, since only the involved spine will be treated, bone marrow will be preserved. The spine is a key blood-forming organ. By reducing the radiation target, organ preservation of the bone marrow can be achieved. This will help facilitate continuation of systemic therapy, which is often essential for this group of patients. Third, radiosurgery is only one treatment as opposed to 10-15 visits for conventional fractionated radiotherapy. It is more convenient for the patient. Equally important is that a single session of radiosurgery does not interfere with ongoing chemotherapy schedules. Fourth, radiosurgery has the potential to be used for decompression of epidural compression. Last, radiosurgery is a non- invasive treatment; it has the potential to reduce the necessity of invasive open surgery in these patients. The non-invasiveness and shortened treatment time provided by spine radiosurgery has great potential to improve the quality of life in this group of patients who can have debilitating conditions and/or neurological deficits. Thus, it is anticipated that in the future image-guided radiosurgery may become a standard of care to treat localized spine metastasis with or without spinal cord compression. Indeed, as this technology is becoming so widely available, this clinical trial is critical to avoid both under-utilization and over-utilization of this emerging technique.

It is important to first study this emerging technique of spine radiosurgery in a phase II trial within a national cooperative group. This phase II study will assess the experience of spine radiosurgery in the RTOG community, which is the optimum forum to test and develop a new radiotherapeutic technology. Once the single arm phase II component is completed and the efficacy of spine radiosurgery is demonstrated, the phase III component will proceed to determine whether spine radiosurgery improves the treatment outcome of spine metastasis as compared to conventional radiotherapy. The phase III component will randomize patients to directly compare a single dose of external beam radiation (8 Gy) versus SBRT given in one fraction (16 Gy or 18 Gy). The result will indeed demonstrate whether or not there is radiation dose-response in pain control of bone metastasis.

1.5 Hypothesis (8/30/11)

In the prior RTOG study for bone metastases, 97-14, the duration and rate of pain control of bone metastases was limited by conventional radiotherapy (single dose of 8 Gy or 10 fractions of 3 Gy for a total dose of 30 Gy) [Hartsell 2005]. Although previous results defined partial pain relief as an improvement of ≥ 2 points, the current trial will define partial pain relief as an improvement of

≥ 3 points to ensure stringent pain control. Complete pain relief will remain defined as no pain, as indicated by a post-treatment score of 0. Both partial and complete pain relief require no increase in narcotic medication. In RTOG 97-14, 253 patients (29% of total) were treated to the spine. The pain response rate was 51% at 3 months in these patients.

The goal of the phase II component of this study is to demonstrate the technical feasibility of treating spine metastases with image-guided radiosurgery/SBRT in the RTOG cooperative group setting. Treatment compliance will be evaluated according to the radiosurgery guidelines (see Section 6.0). Based on the RTOG experience of treating lung cancer with SBRT, the target rate for successful treatment delivery is 85% of patients successfully treated with SBRT for spine metastasis.

The hypothesis of the phase III component, in which patients will be randomized to image-guided radiosurgery/SBRT in a single fraction dose of 16 or 18 Gy (experimental arm) OR conventional external beam radiotherapy in a single dose of 8 Gy (control arm based on the RTOG 97-14 results) is that image-guided radiosurgery/SBRT will result in a 40% improvement (from 51% to 70%) in the proportion of patients experiencing pain relief at 3 months as compared to the external beam radiotherapy. Patients randomized to Arm 1 (experimental arm) will be stratified according to the single fraction dose for image-guided radiosurgery/SBRT, using either 16 or 18 Gy as preferred by the treating physician.

1.6 Primary Endpoint: Numerical Rating Pain Scale (NRPS) (8/30/11)

1.6.1 The primary endpoint is pain control at the treated site(s) at 3 months post-treatment. Pain recurring or progressing prior to 3 months post-treatment is considered a failure. For evaluation of pain relief, the Numerical Rating Pain Scale (Jensen 1999) will be used. The NRPS is a simple measure of pain on an 11-point scale (0-10). In the study comparing the reliability and validity of several measures of pain intensity, the composites of 0-10 ratings have been shown to be useful when maximal reliability was necessary in studies with relatively small sample sizes or in clinical settings in which monitoring of changes in pain intensity in individuals is needed.

1.6.2 Scoring Pain

1.6.2.1 Solitary Spine Lesion

The NRPS will document the status of pain at the treated single spine site.

1.6.2.2 Multiple Spine Lesions

When multiple spine lesions are treated, the index spine lesion will be used to assess the pain response. The index spine lesion is defined as the spine lesion with the highest pretreatment pain score. If a patient has > 1 lesion with the same maximal pain score, the index lesion will be the most cephalad of these lesions. For example, for a patient who has 3 spine lesions to be treated: 1) C5 lesion with pain score of 4; 2) T2-3 lesion with pain score of 6; and 3) T12 lesion with pain score of 6. The index lesion in this case would be T2-3 lesion, as it is the most cephalad lesion among the lesions with the highest pain score. If, however, the same patient had a pretreatment score at T12 of 7 (and the rest of the scores remained the same), the T12 lesion would be the index lesion.

1.6.2.3 Type of Tumor

The stratification between radioresistant tumors and other tumors is due to the similarity of their expected responses. Radioresistant tumors include soft tissue sarcoma, melanoma, and renal cell carcinoma. It has been shown that these types of tumors, specifically melanoma and renal cell carcinoma, appear to have similar responses compared to any other tumor (Gerszten 2005 (c); Nguyen 2010). Thus, these types of tumors are eligible for the study treatment but will be stratified among the treatment groups to not bias the results.

1.6.3 Definition of Pain Response

1.6.3.1 Complete pain relief is defined as a pain score of 0 at the index site at 3 months post-treatment. Complete pain relief is based on no increase in narcotic pain medication.

1.6.3.2 Partial pain relief is defined as a reduction in the numerical pain score of ≥ 3 (i.e., an improvement of at least 3 points from the baseline NRPS) at the index site, as long as none of the other treated lesions have increased in pain score and as long as the patient did not require an increase in the level of narcotic pain medication. Patients who require an increase in narcotic pain medication will not be scored as having partial pain relief, even if their pain score has improved by at least 3 points on the scoring system. (Note: If a patient can only give one pain score for all sites, this score will be used for all treated sites at that time point, and the most cephalad lesion will be defined as the index lesion).

1.6.3.3 Stable response is defined as a post-treatment pain score the same as or within 2 points of the baseline pain score at the index site with no increase in narcotic pain medication.

1.6.3.4 Progressive response is defined as a post-treatment increase of at least 3 points from the baseline pain score at the index site.

1.6.4 Evaluation of Pain Response

Complete or partial pain relief or a stable response at the index site requires no increase in narcotic pain medication and excludes progressive response at the secondary treated site(s). Although complete pain relief is the best outcome, partial relief also is a satisfactory outcome. Therefore, patients with complete or partial pain relief will be considered responders. Patients with complete or partial pain relief at the index site but a progressive response at the secondary site(s) will be considered non-responders.

1.7 Quality of Life Measurements

It is hypothesized that quality of life (QOL) will improve after radiosurgery due to rapid and durable pain control after spine radiosurgery. Indeed, in one study, QOL improved secondary to pain control (Degen 2005). In the current study, we will measure the QOL after radiosurgery using the Functional Assessment of Cancer Therapy: (FACT-G), the Brief Pain Inventory (BPI), and the EuroQol (EQ-5D).

1.7.1 Brief Pain Inventory (BPI)

The pain originating from the spine directly affects the patient’s QOL because the spine is the major weight-bearing area. The Brief Pain Inventory (BPI), developed by Daut, et al. (1983) is a 17-item patient self-rating scale assessing demographic data, use of medications, as well as the sensory and reactive components of pain. The BPI includes items that will address components of sensory pain, including severity, location, chronicity, and degree of relief due to therapy. The BPI also has items that address reactive pain components, such as depression, suffering, and the perceived availability of relief. The scale is from 0-10, and there are breakpoints between scores of 4 and 5 and between 6 and 7, indicating that mild pain correlates with scores of 1-4, moderate pain with 5-6, and severe pain with scores of 7-10. Respectable reliability has been demonstrated using test-retest item correlation (e.g., for worst pain, r = .93). Issues of the validity and reliability of the BPI have been examined in detail (Jensen 1999; Daut 1983). The BPI’s ease of translation and brief administration have made it a frequently used tool in clinical trials where reduction or prevention of pain are the outcome measures. The BPI was previously used successfully in RTOG 97-14 studying patients with bone metastases treated with radiation therapy.

The BPI asks patients to rate their pain for the last week on 0-10 scales at its ‘worst’, ‘least’, ‘average’, and ‘now.’ The scales are presented on a 10 cm line, with each number equidistant from the next. Each scale is bounded by the words ‘no pain’ at the 0 end and ‘pain as bad as you can imagine’ at the other. Using the same type of scales, patients also are asked to rate how their pain interferes with several quality of life domains including activity, walking, mood, sleep, work, and relations with others. These scales are bounded by ‘does not interfere’ at the 0 end and ‘interferes completely’ at the other. Patients also are asked to estimate the pain relief they are receiving from their pain treatment (in percent), to locate areas of pain on a human figure, and to estimate the cause of their pain (cancer disease, cancer treatment, or non-cancer). The patient can complete the BPI in approximately 5 minutes, and the assessment is available in 12 languages.

Issues of the validity and reliability of the BPI have been examined in detail (Daut 1983; Cleeland 1989). The BPI is considered as the FDA standard for a pain assessment tool. The typical standard deviation for the item “worst pain” in most cancer populations is 2.4. Therefore, the finding of a one-point difference in the “worst pain” item at different times or between two comparative groups is considered significant. Translations can be accessed at ; click on “symptom assessment tools”.

1.7.2 The Functional Assessment of Cancer Therapy (FACT-G)

Assessment of pain and its relief also are affected by multiple factors, including the patient’s understanding regarding the nature of pain, and emotional and social background. Therefore, as in RTOG 97-14, the Functional Assessment of Cancer Therapy (FACT-G), v. 4.0, also will be collected. The FACT-G is a commonly used tool measuring the multidimensional components of health related quality of life (HRQOL) across 4 scales: physical well-being (7 items), social/family well-being (7 items), emotional well-being (6 items) and functional well-being (7 items) The FACT, developed by Cella, et al. (1993)., is a five point patient self rating scale (from “not at all” to “very much”). Test-retest reliability is high for the subscales with correlation coefficients ranging from a high of .88 for physical well-being to .82 for social and emotional well-being. It is written at the 4th grade reading level, and patients can complete the FACT-G in 5-10 minutes. The FACT has been translated into more than 25 languages, and translations are accessible at the FACIT web site, .

1.7.3 The EuroQol (EQ-5D)

The EuroQol (EQ-5D) instrument is intended to complement other forms of QOL measures, and it has been developed to generate a generic cardinal index of health, thus giving it considerable potential for future use in economic evaluation. The EQ-5D is a two-part, patient-completed questionnaire that takes approximately 5 minutes to complete(Rabin 2001; Schulz 2002). The first part consists of 5 items covering 5 dimensions including: mobility, self care, usual activities, pain/discomfort, and anxiety/depression. Each dimension can be graded on 3 levels including: 1=no problems; 2= moderate problems; and 3=extreme problems. Health states are defined by the combination of the leveled responses to the 5 dimensions, generating 243 health states to which unconsciousness and death are added (Badia 1998). The EQ-5D has been translated into multiple languages; these translations are available from the EuroQol web site at . The inclusion of the EQ-5D is exploratory, as it allows one to analyze important issues related to quality adjusted survival and cost utility analyses and determine if the instrument should be included in a future phase III trial.

2.0 OBJECTIVES

2.1 PRIMARY OBJECTIVE (8/30/11)

2.1.1 Phase II Component

Determine the feasibility of successfully delivering image-guided radiosurgery/SBRT for spine metastases in a cooperative group setting

2.1.2 Phase III Component

Determine whether image-guided radiosurgery/SBRT (single dose of 16 or 18 Gy) improves pain control (as measured by the 11 point NRPS) as compared to conventional external beam radiotherapy (single dose of 8 Gy)

The endpoint is complete or partial pain relief at the treated index site at 3 months, (as measured by the 11 point NRPS). Complete pain relief is defined as a score of 0 on the NRPS, with no increase in narcotic pain medication. Partial pain relief is defined as an improvement from the baseline NRPS of at least 3 points on the rating scale (and no progressive pain response at any other treated lesion[s], with no increase in narcotic pain medication).

2.2 Secondary Objectives (Phase III Component) (11/6/09)

2.2.1 Determine whether image-guided radiosurgery/SBRT improves the rapidity of pain response at the treated site(s) as compared to conventional external beam radiotherapy, as measured by the NRPS;

2.2.2. Determine whether image-guided radiosurgery/SBRT increases the duration of pain response at the treated site(s), as compared to conventional external beam radiotherapy, as measured by the NRPS;

2.2.3 Compare adverse events between the two treatments according to the criteria in the CTEP Active Version of the CTCAE;

2.2.4 Evaluate the long-term effects (24 months) of image-guided radiosurgery/SBRT on the vertebral bone (such as compression fracture) and the spinal cord by MRI;

2.2.5 Evaluate the potential benefit of image-guided radiosurgery/SBRT on change in and overall quality of life, as measured by the Functional Assessment of Cancer Therapy-General (FACT-G); in pain as measured by the Brief Pain Inventory (BPI); and in health utilities as measured by the EuroQol (EQ-5D);

2.2.6 To implement a well-controlled specimen handling/storage process to facilitate future laboratory correlative studies.

3.0 PATIENT SELECTION

NOTE: PER NCI GUIDELINES, EXCEPTIONS TO ELIGIBILITY ARE NOT PERMITTED

3.1 Conditions for Patient Eligibility (8/30/11)

3.1.1 The patient must have localized spine metastasis from the C1 to L5 levels by a screening imaging study [bone scan, PET, CT, or MRI] (a solitary spine metastasis; two separate spine levels; or up to 3 separate sites [e.g., C5, T5-6, and T12] are permitted.) Each of the separate sites may have a maximal involvement of 2 contiguous vertebral bodies. Patients can have other visceral metastasis, and radioresistant tumors (including soft tissue sarcomas, melanomas, and renal cell carcinomas) are eligible.

See Figure 1 below for a depiction of eligible metastatic lesions: 1) a solitary spine metastasis; 2) two contiguous spine levels involved; or 3) a maximum of 3 separate sites. Each of the separate sites may have a maximal involvement of 2 contiguous vertebral bodies. Epidural compression (arrow) is eligible when there is a ≥ 3 mm gap between the spinal cord and the edge of the epidural lesion (see Section 3.1.10). A paraspinal mass ≤ 5 cm is allowed (see Section 3.1.11).

Figure 1: Diagram of Eligible Metastatic Lesions

[pic]

3.1.2 Zubrod Performance Status 0-2;

3.1.3 Age ≥ 18;

3.1.4 History/physical examination within 2 weeks prior to registration;

3.1.5 Negative serum pregnancy test within 2 weeks prior to registration for women of childbearing potential;

3.1.6 Women of childbearing potential and male participants who are sexually active must agree to use a medically effective means of birth control;

3.1.7 MRI of the involved spine within 4 weeks prior to registration to determine the extent of the spine involvement; an MRI is required as it is superior to a CT scan in delineating the spinal cord as well as identifying an epidural or paraspinal soft tissue component. Note: If an MRI was done as a screening imaging study for eligibility (see Section 3.1.1), the MRI can be used as the required MRI for treatment planning.

3.1.8 Numerical Rating Pain Scale within 1 week prior to registration; the patient must have a score on the Scale of ≥ 5 for at least one of the planned sites for spine radiosurgery. Documentation of the patient’s initial pain score is required. Patients taking medication for pain at the time of registration are eligible.

3.1.9 Neurological examination within 1 week prior to registration to rule out rapid neurologic decline; see Appendix IV for the standardized neurological examination. Patients with mild to moderate neurological signs are eligible. These neurological signs include radiculopathy, dermatomal sensory change, and muscle strength of involved extremity 4/5 (lower extremity for ambulation or upper extremity for raising arms and/or arm function).

3.1.10 Patients with epidural compression are eligible provided that there is a ≥ 3 mm gap between the spinal cord and the edge of the epidural lesion.

3.1.11 Patients with a paraspinal mass ≤ 5 cm in the greatest dimension and that is contiguous with spine metastasis are eligible.

3.1.12 Patients must provide study specific informed consent prior to study entry.

3.2 Conditions for Patient Ineligibility (8/30/11)

3.2.1 Histologies of myeloma or lymphoma;

3.2.2 Patients with any spine metastasis that is not planned to be treated per protocol;

3.2.3 Non-ambulatory patients;

3.2.4 Spine instability due to a compression fracture;

3.2.5 > 50% loss of vertebral body height;

3.2.6 Frank spinal cord compression or displacement or epidural compression within 3 mm of the spinal cord;

3.2.7 Patients with rapid neurologic decline;

3.2.8 Bony retropulsion causing neurologic abnormality;

3.2.9 Prior radiation to the index spine;

3.2.10 Patients for whom an MRI of the spine is medically contraindicated;

3.2.11 Patients allergic to contrast dye used in MRIs or CT scans.

4.0 PRETREATMENT EVALUATIONS/MANAGEMENT

NOTE: THIS SECTION LISTS BASELINE EVALUATIONS NEEDED BEFORE THE INITIATION OF PROTOCOL TREATMENT THAT DO NOT AFFECT ELIGIBILITY.

4.1 Required Evaluations/Management (Phase III Component Only) (8/30/11)

4.1.1 The patient will complete the baseline Numerical Rating Pain Scale (NRPS) on the day of treatment identifying how much pain they are having at the index spine lesion to be treated. The patient can be on pain medication.

Note: The Numerical Rating Pain Scale (NRPS) used to determine eligibility (a required score of ≥ 5; see Section 3.1.8) will not be used to assess treatment response. Documentation of the patient’s initial pain score is required. Treatment response will be assessed by the baseline NRPS completed on the day of treatment. Patients whose day of treatment NRPS score is < 5 remain eligible for the study, will receive treatment, and will be followed per protocol specifications.

4.1.2 If the patient consents to participate in the quality of life component of the study, sites are required to administer the following baseline quality of life questionnaires prior to the start of protocol treatment: The Functional Assessment of Cancer Therapy-General (FACT-G); the Brief Pain Inventory (BPI), and the EuroQol (EQ-5D).

5.0 REGISTRATION PROCEDURES

NOTE: PARTICIPATING INSTITUTIONS MUST IRRADIATE A SPECIAL SPINE PHANTOM IN ORDER TO ENTER PATIENTS ON THIS STUDY. THIS PHANTOM IS DESIGNED TO CREDENTIAL SITES FOR THE IMRT COMPONENT OF THE STUDY. AN ADDITIONAL STEP IS THE CREDENTIALING THAT SITES MUST DO FOR IGRT. SITES PREVIOUSLY CREDENTIALED FOR IMRT AND IGRT WILL NOT BE AUTOMATICALLY CREDENTIALED FOR THIS STUDY. SEE DETAILS BELOW IN SECTIONS 5.1 AND 5.2.

5.1 Pre-Registration Requirements for Spine Radiosurgery/SBRT

5.1.1 The institution must complete all relevant parts of the RTOG Facility Questionnaire: All questions in Part I (General Information for 3D-CRT and IMRT), in Part II (Information Specific to IGRT), and in Part III (Information for Heterogeneity Corrections and Motion Management) must be completed. In addition, an SFTP account for digital data submission must be established, as data will be submitted digitally to the Image-Guided Therapy Center (ITC) [see Section 12.2]. Information for completing both of these tasks is available on the Advanced Technology (ATC) web site at . The ATC is comprised of RTOG RT Quality Assurance, the Image-Guided Therapy Center (ITC) at Washington University, and the Radiological Physics Center (RPC) at MD Anderson Cancer Center.

5.1.2 In addition to the steps described in Section 5.1.1, credentialing for spine radiosurgery includes the process of irradiating the spine phantom provided by the RPC. Instructions for requesting and irradiating the spine phantom are available on the RPC web site at ; select “Credentialing” and “RTOG”. Upon review and successful completion of the phantom irradiation, the RPC will notify both the registering institution and RTOG Headquarters that the institution has completed this requirement.

5.2 Additional Pre-Registration Requirements for Image-Guided Radiotherapy (IGRT) (8/30/11)

5.2.1 IGRT Credentialing Process

5.2.1.1 Prior to entering patients on this study, institutions must perform a verification study. In order to complete the verification study, the institution must do the following:

• Submit a series of planning and localization images along with a spreadsheet of IGRT data to ATC from an anonymized patient treated similarly to 0631 but not accrued to the study.

• The Medical Physics Co-Chair, Dr. Yin, will review the images and spreadsheet and upon his approval of this data, RTOG Headquarters will notify the institution that this part of the credentialing is complete and the institution can continue to enroll patients on 0631.

See the ATC web site, , to obtain the spreadsheet. Since this study involves a single fraction treatment of the spine, simulation images and the treatment plan, onboard localization images (including setup images of simulation position prior to correction , images after reposition prior totreatment, and images of post-treatment) are required. Acquisition of additional images acquired during treatment are encouraged but not required. Pretreatment, during treatment, and post-treatment images may include three-dimensional (3D) volumetric images (either fan- or cone-beam CT with Megavoltage [MV] or kilovoltage [KV] x-rays). Additionally, orthogonal (MV or KV) 2D electronic images can be used.

5.2.1.2 Tolerance Levels for IGRT

Three-dimensional views of gross tumor and other adjacent normal tissue structures, especially the spinal cord, are recommended as reference at the discretion of the treating radiation oncologist. Shifts of patient treatment position can be made based on the pretreatment images. After the position adjustments, the final accuracy of positioning should be < 2 mm identified from the post-shift images, compared with the pre-treatment position.

For those institutions that plan to use orthogonal images for target localization and position adjustment, placement of fiducial markers such as seeds (typically 3 or more) in or outside the gross tumor is recommended. Fiducial markers are often placed under the guidance of ultrasound or CT scan. An orthogonal view of fiducial markers and/or bony anatomy adjacent to the target volume can be used as a standard method. After shifts are made based on the pretreatment images and after the position adjustments, the final accuracy of positioning should be < 2 mm identified from the post-shift images, compared with the pre-treatment position.

5.3 Regulatory Pre-Registration Requirements (3/18/11)

5.3.1 U.S. sites and Canadian institutions must fax copies of the documentation below to the CTSU Regulatory Office (215-569-0206), along with the completed CTSU-IRB/REB Certification Form, . The study-related regulatory documentation may also be e-mailed to the CTSU at CTSURegulatory@ctsu.. This must be done prior to registration of the institution’s first case:

▪ IRB/REB approval letter;

▪ IRB/REB approved consent (English Version)

▪ IRB/REB assurance number

5.3.2 Pre-Registration Requirements FOR CANADIAN INSTITUTIONS

5.3.2.1 Prior to clinical trial commencement, Canadian institutions must complete and fax (215-569-0206) or e-mail (CTSURegulatory@ctsu.) to the CTSU Regulatory Office Health Canada’s Therapeutic Products Directorates’ Clinical Trial Site Information Form, Qualified Investigator Undertaking Form, and Research Ethics Board Attestation Form.

5.3.3 Pre-Registration Requirements FOR NON-CANADIAN INTERNATIONAL INSTITUTIONS

5.3.3.1 For institutions that do not have an approved LOI for this protocol:

International sites must receive written approval of submitted LOI forms from RTOG Headquarters prior to submitting documents to their local ethics committee for approval. See

5.3.3.2 For institutions that have an approved LOI for this protocol:

All requirements indicated in your LOI Approval Notification must be fulfilled prior to enrolling patients to this study.

5.4 Registration (11/6/09)

5.4.1 Online Registration

Patients can be registered only after eligibility criteria are met.

Each individual user must have an RTOG user name and password to register patients on the RTOG web site. To get a user name and password:

▪ The investigator and research staff must have completed Human Subjects Training and been issued a certificate (Training is available via ).

▪ A representative from the institution must complete the Password Authorization Form at and fax it to 215-923-1737. RTOG Headquarters requires 3-4 days to process requests and issue user names/passwords to institutions.

An institution can register the patient by logging onto the RTOG web site (), going to “Data Center Logon" and selecting the link for new patient registrations. The system triggers a program to verify that all regulatory requirements (OHRP assurance, IRB approval) have been met by the institution. The registration screens begin by asking for the date on which the eligibility checklist was completed, the identification of the person who completed the checklist, whether the patient was found to be eligible on the basis of the checklist, and the date the study-specific informed consent form was signed.

Once the system has verified that the patient is eligible and that the institution has met regulatory requirements, it assigns a patient-specific case number. The system then moves to a screen that confirms that the patient has been successfully enrolled. This screen can be printed so that the registering site will have a copy of the registration for the patient’s record. Two e-mails are generated and sent to the registering site: the Confirmation of Eligibility and the patient-specific calendar. The system creates a case file in the study’s database at the DMC (Data Management Center) and generates a data submission calendar listing all data forms, images, and reports and the dates on which they are due.

If the patient is ineligible or the institution has not met regulatory requirements, the system switches to a screen that includes a brief explanation for the failure to register the patient. This screen can be printed.

Institutions can contact RTOG web support for assistance with web registration: websupport@ acr-.

In the event that the RTOG web registration site is not accessible, participating sites can register a patient by calling RTOG Headquarters, at (215) 574-3191, Monday through Friday, 8:30 a.m. to 5:00 p.m. ET. The registrar will ask for the site’s user name and password. This information is required to assure that mechanisms usually triggered by web registration (e.g., drug shipment, confirmation of registration, and patient-specific calendar) will occur.

6.0 RADIATION THERAPY (8/30/11)

THE PRINCIPAL INVESTIGATOR, SAMUEL RYU, MD, AND CO-CHAIRS WILL PERFORM A RAPID REVIEW OF THE TREATMENT PLAN FOR THE FIRST 2 RADIOSURGERY/SBRT CASES FROM EACH INSTITUTION PRIOR TO THE INSTITUTION DELIVERING ANY PROTOCOL TREATMENT ON THE PHASE II COMPONENT OR ARM 1 OF THE PHASE III COMPONENT. INSTITUTIONS SHOULD ALLOW 3 BUSINESS DAYS FOR EACH CASE TO BE RECEIVED, PROCESSED, AND REVIEWED. IF THE PLAN MUST BE RESUBMITTED, IT WILL BE GIVEN A RAPID REVIEW (WITHIN 3 BUSINESS DAYS). TREATMENT PLANS FOR SUBSEQUENT PATIENTS ENROLLED AT A SITE WILL NOT BE REVIEWED PRIOR TO DELIVERY OF TREATMENT, BUT A REVIEW WILL BE PERFORMED AT A LATER DATE TO EVALUATE PROTOCOL COMPLIANCE.

Questions regarding spine radiosurgery/SBRT should be directed to Dr. Ryu (preferably by e-mail, sryu1@, or alternatively by phone, 313-916-1027).

Patients may receive external beam irradiation to other sites, brachytherapy (HDR or LDR), or a combination of external beam irradiation and brachytherapy at the discretion of the treating physician. Dose/duration also will be at the discretion of the treating physician. However, the spine radiosurgery/SBRT and other radiotherapy must not occur at the same time or overlap.

Patient registration must be done within 4 weeks after MRI of the involved spine. Note: The patient will complete the baseline Numerical Rating Pain Scale on the day of treatment.

NOTE: Sections 6.1-6.7 (below) provide information regarding treatment with radiosurgery/SBRT for the phase II and phase III (Arm 1) components of this study. See Section 6.6.2 for IGRT requirements for Arm 1 patients. If the patient is randomized to Arm 2 of the phase III component, see Section 6.8 for details of external beam radiotherapy.

6.1 RADIOSURGERY/SBRT, PHASE II AND PHASE III (ARM 1) COMPONENTS (8/30/11)

IMRT OR OTHER DOSE PAINTING TECHNIQUES ARE REQUIRED FOR RADIOSURGERY/SBRT. 3D-CRT IS NOT PERMITTED.

6.1.1 Dose Specifications

6.1.1.1 Dose Fractionation

Patients treated with radiosurgery/SBRT will receive a prescribed dose of 16 or 18 Gy in 1 fraction to cover at least 90% of the defined target volume (see Section 6.3.1.1). The radiation dose will be chosen based on the treating physician’s discretion and achievement of spinal cord dose constraints as described below. Coverage of target volume < 90% but > 80% is a minor violation, and any coverage < 80% is a major deviation (see Section 6.3.2).

See cord dose/volume constraints in Section 6.3.1.2.

When the patient has multiple spine levels treated, the spinal cord constraint is applied to each treated spine level. The spinal cord volumes are defined based on the image fusion of simulation CT and MRI with T2-weighted and T1-weighted images with contrast. In addition to the spinal cord DVH constraints, the treating physician should review each cross-sectional image to check if there is any excessive radiation dose distribution to the spinal cord.

Radiosurgery should not be used for any cases with a spinal cord dose exceeding the constraints described in this study. Any spinal cord dose that does not meet these criteria is a major deviation (see Section 6.4.1.1).

6.1.1.2 Physical Factors

Photon (x-ray) beams produced by linear accelerators with energies 4-18 MV will be allowed, preferably using photon beams with energy of 6 MV or less. IMRT or other dose painting techniques are allowed. Proton beams, and other charged particle beams (including electrons, heavy ions) are not allowed. Gamma Knife® or Perfexion™ treatment is not allowed.

6.1.1.3 Premedications

No premedications are necessary.

Pain control to help position the patient for the purpose of treatment (not for long-term pain control) is permitted to decrease patient movement due to pain. Note: Narcotics can be used or increased for the purposes of patient positioning for radiosurgery, as clinically necessary; however, the patient should return to the prior level of pain medication after radiosurgery.

If it is necessary to minimize patient’s anxiety about the treatment and disease condition or for immobilization purposes, medications such as alprazolam or lorazepam are allowed.

No steroid premedication is indicated, and it is recommended that all patients receiving corticosteroids begin tapering them immediately after radiosurgery.

6.2 Immobilization, Simulation, and Localization

6.2.1 Patient Positioning

Patients must be positioned in a stable supine position capable for reproducibility of positioning and immobilization from simulation to treatment, allowing the patient to feel as comfortable as possible. Positions uncomfortable for the patient should be avoided to prevent unnecessary movement. A prone position is not allowed. A variety of immobilization systems may be utilized including vacuum bag, alpha cradle, or stereotactic frames that surround the patient on three sides and large rigid pillows (conforming to patients external contours) with reference to the treatment delivery coordinate system. In addition, for cervical spine or cervicothoracic junctional areas, a rigid head and neck immobilization device should be used. Patient immobilization must be reliable enough to achieve the accuracy requirement of image-guidance (see Section 5.2.1.2).

6.2.1.1 Repositioning for Treatment

It is important to reproduce the treatment position. Pain can cause unintended movement, which can prolong treatment time and require repositioning. Therefore, it is important to allow the patient to feel as comfortable as the patient felt during the simulation.

Spine radiosurgery/SBRT is an image-guided procedure. Body frames based only on frame fiducials are not be considered adequate image guidance. Recent development of in-room (or onboard) imaging technology has improved the stereotactic target localization and visualization under image-guidance. These methods can be used where available. Coordinate systems between imaging system and delivery system should be aligned for spine radiosurgery/SBRT. Image data from the repetition of the image-guided maneuver near (prior to the last delivered beam) or at the end of the treatment should be sent to the ITC (see Section 6.2.3).

The treating physician can decide the day of treatment. Treatment can be given on the same day as positioning and simulation when feasible; however, it is not required. It is strongly recommended that institutions treat the patient no later than the day following simulation. For the purpose of rapid review of the first case, institutions should allow 3 business days for their initial case to be received, processed, and reviewed (as specified in Section 6.0).

6.2.2 Simulation

CT simulation will be performed with proper patient positioning and immobilization. It is important to ensure that the target volume is within the attainable range of the frame-based or frameless stereotactic device. CT will be the primary image platform for targeting and treatment planning. The planning CT scans must allow simultaneous view of the patient anatomy and fiducial system for stereotactic targeting. The use of intravenous contrast is strongly recommended as this will help delineate the tumor and normal tissues. Contrast will help visualize the soft tissue and adjacent normal tissues. Axial acquisitions with gantry 0 degrees will be required with slice thickness of ≤ 2.5-3 mm, depending on the manufacturer’s selected slice thicknesses. Images will be transferred to the treatment planning computers via direct lines, disc, or tape.

6.2.3 Localization

Acceptable image-guided techniques include the following. The accuracy of localization should be less than 2 mm from simulation/planning to the end of treatment.

1. Cone-beam CT equipment attached to the linear accelerator, using either the treatment beam or an auxiliary kV x-ray head to obtain multiple projection images for volume reconstruction;

2. Spiral dose delivery equipment that uses the treatment beam to gather helical CT information for image guidance;

3. Any equipment that can produce stereoscopic planar views of the patient in the treatment position, capable of localizing anatomic points in space or viewing implanted fiducial markers. It can use the treatment beam with a standard electronic portal imaging device (EPID) or a kV x-ray source with opposed imaging panel.

4. A standard diagnostic-quality CT scanners positioned in the treatment room and geometrically coupled (e.g., on rails) with the treatment equipment.

Although film procedures could fall under the description given in item 3 above, there are certain limitations that make it difficult to extend the definition to include this technology. A major limitation for film is that it must be scanned with a densitometer to convert this information to digital data. Additionally, in order to use this digital data in the fusion process, the film must be held perpendicular to the direction of the beam. Although possible, this geometry is not available on most linear accelerators. Thus, radiographic film is not allowed as an image-guided technique for this study. However, film is allowed as a double check to verify the positioning obtained with any of the accepted IGRT techniques.

Institutions are required to save and forward all the images used for patient setup adjustments. These images must be sent in DICOM format to the ITC, . This must include both the IGRT images and the treatment planning images.

6.3 Treatment Planning/Target Volumes (8/30/11)

6.3.1 Target Definition

Image fusion between MRI (gadolinium contrast T1-weighted and T2-weighted images) and simulation CT is required for delineation of both the soft tissue tumor component and the spinal cord. Special attention should be taken with image fusion when simulation CT and MRI images are taken in different imaging positions. Spine curvature of MRI and CT simulation usually is not aligned well. In this situation special attention should be given to fuse the target spine to be treated. It is recommended but not required that MRIs are obtained with the simulation position. MR simulation should be used where available.

6.3.1.1 Radiosurgery Target Volume

The radiosurgery target volume includes only the involved vertebral body and both left and right pedicles as shown in Figure 2 below and the grossly visible tumor, if a paraspinal or epidural lesion is present. An epidural lesion is included in the target volume provided that there is a ≥ 3 mm gap between the spinal cord and the edge of the epidural lesion. A paraspinal mass ≤ 5 cm in the greatest dimension contiguous with spine metastasis is included in the target volume. In this study, the terms, GTV or CTV, are not used.

The target as defined above will not be enlarged (i.e., no “margin” for presumed microscopic extension). This target volume ultimately becomes the radiosurgery planning target volume. The radiosurgery does not assume set-up errors. However, depending on the radiosurgery system, a beam aperture margin of 2-3 mm beyond the target volume is allowed to meet the adequate dose coverage of the target. This margin can be reduced to 0-1 mm at the area of spinal cord to meet the spinal cord dose constraints. The treatment plan is acceptable as long as ≥ 90% of the target volume receives the prescribed radiosurgery dose.

Examples of radiosurgery target volumes are illustrated in Figure 2. Solid black represents the tumor that can be seen on the imaging studies.

Most of the spine metastases involve the vertebral body and the gross tumor seen on MRI or CT scan, as shown in Figure 2a below. This is the most common type of spine metastasis. The radiosurgery target volume includes the involved vertebral body and both pedicles (solid red line).

Metastatic lesions can be more extensive, involving the pedicles [Figure 2b]. The target volume can be more generous [dotted line of Figure 2b], or the target volume can include anterior and posterior elements of the spine [solid red line of Figure 2b]. The target volume may be chosen at the discretion of the treating Radiation Oncologist based on the extent of tumor involvement.

When the metastasis involves only the posterior element, the target volume includes the spinous process and laminae [solid red line of Figure 2c].

In any circumstance, when there is an epidural or paraspinal soft tissue tumor component, the visible epidural or paraspinal tumors are included in the target volume.

[pic]

Figure 2: Diagram of Spine Metastasis and Target Volume

6.3.1.2 Spinal Cord Volume

Two spinal cord contour sets are required for this protocol: the conventional and the partial spinal cord volumes.

The conventional spinal cord volume is contoured on the simulation CT based on the image fusion with T2-weighted and T1-weighted MRI with contrast. It is recommended that a simulation CT be done with contrast, but this is not required. The conventional spinal cord should be contoured starting at least 10 cm above the superior extent of the target volume and continuing on every CT slice to at least 10 cm below the inferior extent of the target volume. This spinal cord volume is required to be consistent with image-guided radiotherapy volume definition of RTOG protocols.

The partial spinal cord volume is specific to this study. The definition of partial spinal cord volume is shown in Figure 3below. The spinal cord is contoured based on the image fusion with T2-weighted and T1-weighted MRI with contrast. It is recommended that a simulation CT image be done with contrast, but this is not required. The partial spinal cord should be contoured starting from 5-6 mm above the superior extent of the target volume to 5-6 mm below the inferior extent of the target volume. The spinal cord should be drawn on every slice of simulation CT. The variation of 5-6 mm is due to the pre-determined slice thicknesses of 2.5-3 mm by different CT manufacturers.

Three cord dose constraints are used in this study: 1) the dose constraints for the partial spinal cord is 10 Gy to no more than 10% of the partial spinal cord volume; or 2) the dose constraint for the conventional spinal cord is 10 Gy to the spinal cord volume less than 0.35cc; or 3) the maximum cord dose is 14 Gy for less than 0.03cc. These constraints are applied to the treated spine level. Any spinal cord dose exceeding these constraints is not acceptable and is a major deviation.

Figure 3: Diagram of Defining Partial Spinal Cord Volume

[pic]

Radiosurgery is not recommended for any cases that do not meet the spinal cord constraints. Each CT slice within the radiosurgery plan should be checked to screen any unacceptably high radiation dose to the spinal cord at any particular slice. In this situation, the treating physician can make the decision of proceeding or stopping the radiosurgery or to perform re-planning. Critical organs including spinal cord, liver, kidneys, and lung should be analyzed for radiation dose distribution if any of them are transected by any radiation field. The dose-volume guidelines are described in Sections 6.3.2 and 6.4.

6.3.2 Dosimetry

Intensity-modulated radiation therapy (IMRT) or other dose painting techniques will be used to deliver highly conformal dose distributions. Non-coplanar beams can be employed. Non-opposing beams are preferable. Multiple beam directions or arcs of radiation will be used for geometrically complicated lesions. The beam arrangement should be placed mostly from the posterior direction to avoid the radiation beam entering through the lungs. Intensity-modulated arc therapy with either multiple static cones or dynamic conformal multileaf collimators (MLC) can be used. For arc rotational techniques, every effort should be used to limit the radiation through the lung.

A common point should be defined, which is close to the center of the target volume for dose normalization. Preferably, this point is placed at the treatment isocenter if a linac based delivery system is used. The plan should be normalized to the common point or isocenter or its vicinity suitable for dose normalization. Typically, this point will be the isocenter of the beam rotation; however, it is not a protocol requirement for this point to be the isocenter. Inhomogeneity correction must be included for dose calculation. The prescription dose of 16 or 18 Gy will be delivered to the margin of the target volume and fulfill the requirements below. The treatment plan is acceptable as long as > 90% of the target volume receives the prescribed radiosurgery dose.

Successful treatment planning will require accomplishment of all of the following criteria:

1) Prescription Isodose Surface Coverage

Patients will receive 16 or 18 Gy in 1 fraction of radiosurgery. This study requires 90% coverage of the target volume by the prescribed dose. Typically, the 80-90% isodose line is used as prescription line. Depending on the delivery system, this prescription isodose line may be different. Coverage of < 90% of the target volume is a Variation Acceptable, and any coverage of < 80% of the target volume is a Deviation Unacceptable.

2) Target Dose Heterogeneity

The treatment plan is per protocol as long as ≥ 90% of the target volume receives the prescribed radiosurgery dose. Dose inhomogeneity can exist within the target volume.

3) High Dose Spillage

Because of the irregular shape of target volume and the position of the spinal cord, there can be hot spots in the immediate vicinity outside of the target volume. The area of hot spot often can be seen in the immediate paraspinal areas or within the paraspinal muscle (e.g., psoas) or rib cage including intercostals muscle. Dose spillage is considered to be Per Protocol if the following dose limits are met. Plans that do not meet these limits are scored as either Variation Acceptable or Deviation Unacceptable (see Section 6.6.1.1).

The Per Protocol plan:

• limits dose outside of the target volume to greater than or equal to 105% of the prescription dose to a volume of less than or equal to 3.0 cc ;

• limits dose of greater than or equal to 105% of the prescription dose to a region within 1.0 cm from the edge of the target volume ;

• excludes all doses of greater than or equal to 110% of the prescription dose outside of the target volume.

It is important to point out that these dose limits do not override the dose restrictions for the spinal cord stated below in Section 4 (Spinal Cord Dose) and in Section 6.4.1.1. The high dose spillage conditions can be determined by expanding the target defined in Section 6.3.1.1 by 1 cm. Examination of the DVH for this rind around the target will determine the size of any high dose regions outside the target. If the region of dose higher than 105% of the prescribed dose is seen to go outside of this margin region, the case will be scored according to the rules in Section 6.6.1.1.

4) Spinal Cord Dose

The most important requirement is the spinal cord dose constraint 10 Gy to the 10% of the partial spinal cord volume defined as 5-6 mm above and below the target. For multiple lesions, the partial cord volume and the 10% volume will increase. In no case should the dose of 10 Gy be exceeded for a spinal cord volume of 0.35 cc. The absolute maximum dose to any part of the spinal cord will be 14 Gy for a volume of 0.03 cc.. Radiosurgery should not be used for any cases with spinal cord dose exceeding the described constraints in this study. Any spinal cord dose that does not meet these criteria is a major deviation.

5) Low Dose Spillage

The falloff gradient beyond the target volume extending into normal tissue structures must be rapid in all directions and meet the following criteria: Using radiation beams directed from posterior to minimize passage of radiation through the lungs is strongly recommended.

6.4 Critical Structures (8/30/11)

6.4.1 Critical Organ Dose-Volume Limits

The following table lists maximum dose limits to a point or volume within several critical organs recommended for stereotactic body radiation therapy (SBRT). The recommended dose constraints are shown in volume and the maximum dose to the given volume for each organ (Timmerman 2008). Note: The dose to the spinal cord has been modified from the original publication.

Table 1: One Fraction Dose Constraints for Arms 1 and 2

|Serial Tissue |Volume |Volume Max (Gy) |Endpoint (≥ Grade 3) |

| | | | |

|Spinal Cord |Less than or equal to 0.35cc |10 Gy |myelitis |

|AND |

|Spinal Cord |Less than or equal to 10% of |10 Gy |myelitis |

| |the partial spinal cord | | |

|AND |

|Spinal Cord |Less than or equal to 0.03cc |14 Gy |myelitis |

|Cauda Equina | ................
................

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